DE2359732A1 - ARRANGEMENT FOR STABILIZING THE REINFORCEMENT OF A RADIATION DETECTOR - Google Patents

Description

to the patent application

the Societe de Prospection Electrique Schlumberger, 42, rue Saint-Dominique, Paris / France

concerning:

"Arrangement for stabilizing the gain of a radiation detector"

The invention relates to stabilizing the gain of radiation detectors . In particular, it relates to an arrangement intended to stabilize the gain of radiation detectors usable in spectrometry, ie detectors which deliver a signal proportional to the energy received, such as semiconductor detectors or scintillation detectors. -

In particular, the invention relates to the STabilization of the amplification of photo multipliers, which are used in tools - which are used in oil exploration for measuring the density of geological formations, which are penetrated by a borehole can be used. -.

409826 / 0SS7

As is known, the density in boreholes is measured by means of a device which comprises a gamma ray source and a radiation detector, generally consisting of an assembly with a scintillation body and a photomultiplier, at a distance of about 40 cm from the source. The radiation emitted by the source loses its energy in the formations in principle. Collision with the electrons, and part of the radiation returns to the detector, which accordingly registers a field rate that is lower, the closer the number of electrons per unit volume in the formation. The density of the formations, which is directly related to the number of electrons, can be derived from the counting rate in this way. In FIG. 1, the energy spectrum is plotted in semilogarithmic coordinates of the gamma rays which strike the detector for three decreasing values d, d and d of the density, ie the curve shows the logarithm of the probability N (E) of the reception of a ray of energy E. in function of this energy. It can be seen in this figure that below a threshold E (of the order of magnitude of 2oo keV) the changes in density cause a distortion of the spectrum, but that above this threshold, these deformations are not present; the number dex · gamma rays with an energy above E is a descending exponential function of the density. Under these conditions, only the pulses with an amplitude above a threshold S, corresponding to captured Gantssia radiation with an energy above E, are detected at the detector output. The registered count rate accordingly allows _f to derive the value of the density.

It is easy to see that this technique is necessary in order to be able to provide useful results makes that the gain of the detector system is stable,

ie that a gamma ray of given energy always triggers a pulse of the same amplitude. Every change in the gain results in a shift in the spectrum and is equivalent to a shift in the threshold / which accordingly leads to a shift in the counting rate and thus falsifies the density measurement. For example, in Fig. 2 for. three different values of the gain G, G- and G_ recorded the spectrum of the pulse amplitudes at the output of the detector, ie the curve which gives the probability N (A) of obtaining a pulse of amplitude A as a function of this amplitude. It turns out that when defining the counting threshold S for a value G _{2 of} the gain, an increase of the same to the value G_ corresponds to a lowering of the threshold and accordingly leads to a counting of additional pulses. Conversely, a reduction in the gain to the value G ₁ leads to an increase in the threshold and thus results in a loss of pulses.

On the other hand, it is known that the detector systems and especially the photomultiplier machines show very noticeable gain factor changes as a result of changes the temperature and those that influence the count rate itself. It is therefore essential to correct this Provide gain changes.

One already has the amplification of photo multipliers stabilized by the fact that their supply voltage or the gain of the output amplifier to the Adjusted the position of an artificially created reference spike which lies outside the spectrum used for the measurement itself and is generated by an alpha or gamma ray source, which is assigned to your scintillation body, or by a sehi: stable source that is directly on the

28/09

Photomultiplier cathode is shining. More precisely, one generates a signal which is representative of the difference between the registered count rate for two narrow power windows chosen on the two Flanks of the reference peak. The changes in the amplification factor of the photomultiplier resulting in a displacement of the Lead, accordingly results in an imbalance between the two counting rates, which is represented by a signal, which accordingly acts on the value of the high voltage of the photomultiplier or on the amplification factor of the Output amplifier to lock the tip in the same position inside.

To date, this solution has not produced completely satisfactory results. If namely to capture every displacement of the reference peak with great accuracy and for quick adjustment a source of high If the intensity is used, which has a low noise component, the measurements will be disturbed by the Presence of the Compton background radiation associated with such a significant peak. Conversely, to avoid incorrect measurements due to the Compton background radiation uses a low intensity source that has a high statistical noise content, the detection of the gain changes is less accurate, the correction is less rapid and requires a The length of time, the longer the greater the disturbance.

In other words, a strong source of supply brings with it little statistical noise and allows accordingly a fast adjustment, however, interferes with the measurements, while a weak source admittedly interferes with the measurements not bothering, but a significant statistical

AÖ9S26 / 09B7

Has a noise component and therefore only allows slow adjustment. For this reason one has so far with a compromise solution in which one is sufficient weak source used to be too large To avoid disturbing the measurements, however, a source that was still strong enough to keep the rain! not to let it become too slow, especially in the case of large changes in the gain factor.

The object of the present invention is to show a solution for this dilemma. So it should be a Source of weak intensity can be used and still have a high speed of response to gain changes guaranteed to be practical in addition should be independent of the magnitude of the gain variations.

Based on an arrangement for stabilization the amplification of a radiation detector with a radiation source, which allows a reference figure to be generated in the output signal spectrum of the detector, with a detection device for the displacement of this figure as a result of changes in amplification factor to generate an actual signal, its amplitude for the size and its sign for the direction of displacement is representative, and with one Control device that controls the gain from the ISt signal Affected to the reversal of the offset, this object is achieved according to the invention in that when using a radiation source of low intensity an amplitude modulator is connected between the detection device and the control device, which modulates the amplitude of the actual signal is modulated according to a function of this amplitude that is non-pair and one from the origin in its absolute value has increasing derivative, and that the actual signal modulated in this way is fed to the control device.

409826/0987

- -. .6 -

Accordingly, in the arrangement according to the invention, the signal representing the actual state is subject to before it is used to correct the migration or deviation, a gain that is all the greater the greater the emigration. The arrangement accordingly has a tendency to reduce the gain changes with all the more The higher the speed, the more significant the deviations are, which compensates for the delaying effect due to the statistical error due to the use of a source of low activity, and this is all the more noticeable, the greater the variations to be corrected, under these conditions a Response speed that is practically independent of the magnitude of the gain changes. The system owns in equilibrium, as will be explained in more detail below, low sensitivity to noise.

The modulation is advantageously implemented according to a hyperbolic sinus function, i.e. that of the Control device supplied and used for the control signal proportional to the hyperbolic sinus of the The actual signal is the deviation of the gain factor represents. -

Further features of the invention emerge from the attached patent claims. With reference to the accompanying drawings, a preferred embodiment is shown below the arrangement according to the invention explained in more detail:

Fig. 1 shows for a device that is used for density measurement in geological formations, the influence of density changes on the energy spectrum of detected gamma radiation,

409826/0987

Figv ^v r-2 shows the influence of the gain factor changes in the detector on the amplitude spectrum of the pulses which

ί · ώ. «; ί? ρΛ: ■. ■ - ■ - ;; -_. ί; '; ^ are given by him,

Fig »3 - '■ shows schematically an arrangement according to the invention,-

Fig. 4 shows the Im- in the amplitude spectrum of the pulses generated by the detector. pulse - peak.,

FIG. 5 shows in detail the modulator of the arrangement according to FIGS. 3, and

Fig. 6 shows the response curve of this modulator

In Fig. 3 is a photomultiplier at Io or 12 shown with an associated scintillator, as they are commonly used, e.g. in the case of a density diagrammatic device to intercept the gamma radiation that is backscattered by a ümgependen body 14. The photo multiplier is fed by a high voltage source 16, the level of which is adjustable by means of a to a Staieringang 18 applied control voltage. The output impulses of the photomultiplier Io go to an amplifier 2o, the output of which is connected to a processing stage 22, the task of which is to measure the density of the To calculate milieus 14, assuming the counting rate of the captured pulses. '

The stabilization of the amplification of the photomultiplier is ensured by

409826 / Ö.ÖI7

- a gamma ray source 24 which is inserted into the scintillation body 12 is built in and serves to create a reference peak (Fig. 4) outside (in the energetic section) of the spectrum of the pulses delivered by the amplifier 2o (diffusion spectrum, and through a

- Arrangement, generally indicated by the reference numeral 26, whose function is to provide the Undo and correct migrations of the peak due to changes in the gains affecting the level of the high voltage supply of the photomultiplier.

In order to avoid disturbing the measurements, the gamma source 24 has an activity of a few micro-curies, which is therefore very weak, and of course one chooses it so that the reference peak that arises is clearly outside the Diffusion spectrum is used for the measurement.

As an example of a diagrammatic measuring device, in which the spectrum barely exceeds 45o keV, the use of a. awei microcurie source. called by Cs 137, its photoelectric Peak is at 661 keV «.

In the / arrangement 26, the pulses occurring at the output of the amplifier are fed in parallel to three energy comparators 28, 3o and 32, which each have the amplitudes A, K and A ₃ as tensile stresses. Figure 4 shows how these three values are chosen. The amplitude A _? corresponds to the peak S of the reference peak for a certain gain which is to be kept constant, while the amplitudes A ^ and A ^ are assigned to two homologous points F and F ^1, respectively, at the base of the flanks of the peak. The vertical of these two points delimit with the vertical through the point S.

two zones of the same area. Accordingly, the count rate is N of pulses with amplitudes between A and A “equal to Counting rate N ~ of the pulses with amplitudes between A_ and A .. For example, with a source of GS 137 with an activity of two microcurie, the count rate of the pulses is with amplitudes between A and A_, about 2oo per second =

The outputs of the three comparators are applied to an anti-coincidence logic circuit 34 which comprises an inverter circuit 36, an AND gate 38, a NON-QDER circuit 40 and a bistable trigger circuit 42. The output of the comparator 3o is via the inverter switching circuit 36. one input of the AND gate 38 and one input of the IMPORTANT-OR circuit 4.o. The output of the comparator 28 is connected to the other input of the AND gate 38 and that of the comparator 32 is connected to the other input of the NOT-QDER circuit 4o. Finally, the reset input of the bistable trigger circuit 42 is connected to the output of the KICHT-OR circuit, while its set input S is connected to the output of the AND gate. The output Q of the breakover circuit is connected to the input of a low-pass filter 44. Is this an RT filter? its cutoff frequency is 2 Hz for a source _e that delivers a counting rate of 2oo per second between A and A-. The output of this filter is connected to the input 46 of a nonlinear modulator circuit 48, which supplies a voltage ν at its output 50 which is approximately proportional to the sine hyperbolicus of the voltage ν at its input 46. Finally, the modulator is followed by an integration stage 52 whose output is connected to the control input 18 of the high voltage supply source 16 ..

5 shows schematically the advantageous embodiment of the modulator 48. It consists of five branches 54, 56,

-Io -

58, 6o and 62, which are between the input 46 and the output 5o are connected in parallel and each include:

- a resistor 6 4 of size R,

- A resistor 66 of size R "and a diode 6Ö

in row,
a wid <
in row,
a wid <
in series or
a widi
in row;

a resistor 70 of size R “and a diode

a resistor 74 of size R_ and a diode

- a resistor 78 of the size R .. and a diode

these four diodes are similar to one another. The only difference between the branches 56 and 58 lies in the fact that the diode 6 8 of the branch 56 is connected to the output 5o at its cathode, while the diode 72 of the branch 58 is connected to its anode at the output. Likewise, the difference between branches 6o and 62 is the polarity of diode 76 of branch 6o, which is connected to output 5o with its cathode, compared to the polarity of diode 8o of branch 62, whose anode is connected to the output and 8o connected with its cathode to a voltage source + V, respectively via a resistor 82, the size of R ₄ and a resistor 84 the size of R _5, and the diodes 68 and 76 are connected with their cathode to a voltage source -V "jjwaiis via a resistor 86 of size R ₄ or a resistor 88 of size R ₅ -

It is easy to find the potentials v ,, _D , v _Ä .,. ,,. If _x , -, -, and

Ao ο A / d is. IZ

K80 at the anode of the diode 60 _{r of} the anode of the diode 76 and the cathode of the diode 72 and the cathode of the diode, which can be expressed as a function of the voltage ν at the input 46 according to the following equations:

- 11 -

V.
e ^R 4 - V ^K 2 ^V A6 8 ^R 2 + R 4th V R- -V ^R 3 ^R 3 j_ "D 5 V R. + V R ₂ V.
e ^R 5 + V R ₃ ^V K8o ^R 3 + R

Under these conditions and taking into account the fact that the ratio R ₂ / ^R 4 is selected to be ^smaller than the ratio R ₃ / R_, it can be seen that as long as the voltage at the input ν rises from zero, the four diodes all polarize in the reverse direction are, then the diodes -6 8 and 76 in the forward direction successively starting from ν = VR ₉ / R _d and ν = VR / R _1, respectively. polarity can be reversed as long as the voltage at the input ν starts from tfull-

fei

falls, the four diodes are initially polarized in the reverse direction and then the diodes 72 and 8o are redesigned in Durchlaßricntung, one after the other starting from ^v e ⁼ " ^VR 2 ^{/ R} 4 ^{and V} e ⁼ " ^VR ₃ / ^R ₅ °

Accordingly, it results that with a sensible selection of the values of R, R ₃ , R ₃ , R. and R- one can build up a network 48 with a response curve i = f (v), as shown in FIG. 6, where i is the current at the input

output of the integrator is impressed. This curve approximately represents the function i. = K.sin hyp ν, realized by five straight sections A, B +, C + ,. B- and C- "Section A corresponds to the area for which the four diodes are biased in blocking; the branches 56 ', 58, 60 and 62, which contain the diodes, show ^:

measured a high resistance such that the equivalent resistance of the network is substantially equal to R ₁ .

The gate B + corresponds to the area for which the diode 6β, now operated in Uurchlaßrintung, connects the resistor 66 in parallel with the resistor 6 4 in such a way that the equivalent resistance of the network is essentially equal to RR / (R + R), i.e. below R ₁ .

The section C + corresponds to the area in which the diodes 6ö and 76, both forward-biased, the resistors 66 and 74 parallel to the resistor 64, so that the equivalent resistance of the network im

substantially equal to R ₁ RR / (R ₁ R ₃ + R ₁ R ₃ + R ₃ R ₃ ) and will therefore be below R ".

Section B- is the negative homologue of B + and corresponds to the area in which diode 72 is now conductive, the resistor 7o connects the resistor 64 in parallel, so that the equivalent resistance of the network becomes substantially equal to R R / (R + R).

Finally, the section C- is negatively homologous to C + and corresponds to the area in which the diodes 72 and 8o, both forward-biased, connect the resistors 7o and 7b in parallel with the resistor 64 such that the equivalent resistance of the circuit is essentially equal to RR ₃ R ₃ / "(RR ₃ + R ₁ R ₃ + ^R ₂ ^R 3).

If, in summary, the input voltage ν increases, appropriately selected resistors are connected in parallel to the basic resistance 64, and accordingly reduce the effective resistance of the network, so that there is an increase in the proportionality factor between the Input signal and the output signal, with which the

- 13 -

/, 09826/09 8?

Curve i = f (ν) follows the function i = k. sin hyp ν se ^s *

adapts.

Clues can be given:

Section A extends from V ₃ = - 4 V to ν = + 4V with an increase of 0.4

the section B + extends from ν = ■ + 4V to

ν = + SV with an increase of 1.5 p \ A / V,

the section C + extends in the area above ν = + S V with an increase of 7 ΑλΑ / V,

the section B- extends from ν = -4 V to ν = + 8 V with an increase of 1.5 yu ^ A / V, and

the section O extends beyond ν = - 8 V with a slope of 7 ^ A / V. These data are obtained with R - 1 Megohm, R ₃ = 38o KOhm, R- = 7o KOhm, R ₄ = 54o KOhm and R- = 45 KOHm.

One can now explain the function of the arrangement according to FIG. First of all, it should be noted that the pulses at the output of the amplifier 2o, if they have an amplitude below A, do not affect the comparators 28, 3o and 32; if they have an amplitude above A ₁ but below A ₂ , trigger the comparator 28, but leave the other two comparators unaffected; if they have an amplitude above A but below A ₃ / trigger the comparators 28 and 3o, but leave the comparator unaffected, and trigger all three comparators _{at an amplitude above A 3.}

under these conditions, a pulse at the output ^ of the amplifier 2o with an amplitude below A or above A _{3 is} not processed by the logic circuit 34.

If, however, a pulse with an amplitude between A ^ and A ^ appears, Deide inputs of the üWu-Ciatters 38 are at L, while the inputs of the NICIIT-OR circuit 4o are at L 'or zero; the output of the AND gate is accordingly at L and that of the NOR circuit at WuIl, such that the bistable Kippkfeis 4 2 receives a pulse at its reset input R, which flips into the switching state L \ iull. In the case of a pulse with an amplitude between A ₂ and A ^, on the other hand, both inputs of the OÜER gate 38 are on L or wull and the two inputs of the üICHT-OR circuit are in Mull; the output of the AND gate is accordingly at zero and that of the NOR circuit is at L, so that the bistaoile trigger circuit 42 receives a pulse at its set input S which switches it to the L switching state.

The output Q of the trigger circuit 42 accordingly assumes the switching state zero for a pulse with an amplitude between A and A _? and the switching state L for a pulse with an amplitude between A and A, and the level at the output of the low-pass filter 44 is representative of the deviation between the counting rates N ₁ and Ν- of the pulses with amplitudes between A and A "or A ₂ and A ,. More precisely:

If the gain remains at its reference value, for which the two counting rates are equal, the mean voltage at the output "of the filter is NuIl; if the voltage increases and accordingly causes a shift to the right of the reference peak, corresponding to a decrease in N, and a Increasing N ₂ , the mean voltage at the output of the filter has a positive value, proportional to the equilibrium between the two counting rates *, if the gain decreases and thus causes a migration to the left of the reference peak, corresponding to a decrease

from Α- _? and an increase of N ₁ , the mean voltage at the output of the filter has a negative value, proportional to the imbalance between the two counting rates.

This voltage is the voltage v _{e #} which arrives at the input 4b of the modulator 4b. This works as explained above and accordingly supplies a voltage v. At its output 5o, approximately proportional to the sinus hyperbolicus of ν. The integrator 52 is fed with this voltage and accordingly applies a continuous voltage to the control input 18 of the high-voltage supply source 16 of the photomultiplier, which is intended to stabilize the gain at the reference value. Expressed differently:

If there is no change in the gain factor, is the mean voltage that is fed to the integrator, Zero and the high voltage on the photomultiplier remains unchanged; when an increase in gain is detected has the mean voltage that is fed to the integrator becomes, a negative value, proportional to the hyperbolic sinus the difference between the two count rates. This "voltage" accordingly reduces that across the photomultiplier applied voltage until this difference is canceled; if a decrease in gain is found the mean voltage at the input of the integrator is positive with a value prioportxonal to the hyperbolic sinus the difference between the two counting rates? this voltage accordingly increases that applied to the photomultiplier Tension up to. Cancellation of the difference.

In this way, a change in the gain factor of the detector system with the aid of an error signal corrected, which is approximately proportional to the hyperbolic sinus of the deviation, i.e. (since the function Hyperbolic sinus one from the origin in its absolute value

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AO 9 8 26/09 8 '?

constantly increasing derivative) with the help of an error signal proportional to the change, where the The proportionality factor itself is an increasing one Function of this change is. In other words, when a gain change is detected, they tend to be comed at a rate that is greater, the greater the deviation. It is known that when using a very low activity source, the statistical error related to the Detection of gain changes has the consequence that the time required for the correction is increased. This effect is all the more pronounced when the the deviations to be corrected are larger. The arrangement according to the invention allows this phenomenon to occur in to reverse its opposite and has a tendency to correct the changes in gain the faster the bigger they are. In this way, even if a weak source is used, the response speed to gain changes will be improved is increased considerably and is essentially independent of the size of these deviations Value.

As an example it can be stated that in a realized arrangement a disturbance of 100% to 1% in one Period is returned, which is six times smaller than an arrangement of the same construction, but without Modulation of the actual signal.

It is also important to note that if the disturbance is absent, the system in the zone slight rise in the response curve of the modulator ar-Deits. The input of the integrator is accordingly at a level close to zero, which is of course the arrangement in Equilibrium state has a low sensitivity to

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409826/0 98?

Confers noise interference *

It goes without saying that the invention is not

is limited to the embodiment described, but also allows deviations in parts or in total of the described arrangement - within the framework of the Equivalents, as well as regarding application to similar ones .or other arrangements. For example, it is obvious that the correction of the gain changes is not just about der Hochspanriüngsversorgüngsquelle «can follow, but also ah is the gain of the output amplifier for the detector. ·

(£ ätentan's claims)

Claims (8)

Claims l.y arrangement for stabilizing the amplifier of a Radiation detector with a radiation source in the output signal spectrum of the detector allowed to generate a drawing figure, with a detection device for the Displacement of this figure as a result of gain changes to generate an ACTUAL signal, its amplitude is representative of the size and its sign for the direction of the displacement, and with a control device, which, controlled by the actual signal, influences the gain until the offset is reduced, characterized in that, that when using a radiation source of weak intensity between the detection device and the control device is connected to an amplitude modulator which controls the amplitude of the actual signal according to a function this amplitude is modulated, which is not paired and a derivative that increases in its absolute value from the origin and that the actual signal modulated in this way is fed to the control device, 2. Arrangement according to claim 1, characterized in that the amplitude modulator according to a non-linear function is designed to work to generate an output 'signal that is approximately proportional to the hyperbolic sinus of the signal present at its input. 3. Arrangement according to claim 2, characterized in that that the nonlinear modulator comprises: a) 2 n + 1 resistors connected in parallel between the modulator input and the ilodulator output 1 i e, - 19 - 4G982B / Ö98? b) first switch elements, the η of these resistances are assigned to switch on each of them at a predetermined positive value of the input signal, b) second switch elements, assigned η further Resistors for switching on each of them, based on specified negative values of the input signal .. 4. Arrangement according to claim 3, characterized in that the first and second switch elements comprise diodes in series with resistors in such a circuit arrangement that the diodes of the first switch elements in Forward direction are polarized, starting from the predetermined positive input signal values, and those of the second switch elements are polarized in the reverse direction, starting from the specified negative values of the input signal 5. Arrangement according to claim 1, characterized in that that in the case of a reference figure designed as a peak, the detection device includes: a) three voltage comparators. those for reception formed and connected by pulses generated by the detector, and amplitudes corresponding to the peak of the peak as reference voltage and two homologous points are supplied on its flanks, b> an anti-coincidence logic circuit which is connected to the outputs of these three comparators "and is designed to generate a binary signal whose" two _: switching states pulses "of the detector are assigned with amplitudes wiping the" amplitude of the peak tip and the one or another amplitude 2B./P9 87 - 2ο - corresponding to the homologous points on the peak flanks, c) a filter circuit which is connected for the reception of the binary signal and for the generation of a Signal is formed, the mean level and its sign are representative of the deviation between the durations of the two binary states and the direction of this binary addendum. 6. Arrangement according to claim 5, because it is marked, that the anti-coincidence logic circuit comprises: a) an IMD gate, one input with the output of the comparator is connected to the lowest reference voltage, b) a NOR circuit, one input of which is is connected to the output of the comparator with the highest reference voltage, c) an inverter circuit between the output of the comparator with the reference voltage corresponding to the amplitude at the top of the reference peak and the others Inputs of the IMD gate and the rJICHT-QDER circuit is switched, and d) a bistable trigger circuit, its set input with the output of the AND gate and its reset input is connected to the output of the NOR circuit, such that the binary signal appears at its output. 7. The arrangement according to claim 1, characterized in that the control devices an integrator ate un, which is connected to the - 21 - U 09826/0987 aiaplitude modulated. Signal is activated 'and its The output supplies a continuous signal for the correction of the Power supply of the detector or the amplification at its exit. 8. Arrangement according to one of the preceding claims, characterized in that the. Radiation source "a Cs 137 source with an activity voawemigen / -ν Curie is » 4D3826 / QS8?